mojo/edk/system/channel.cc - external/github.com/flutter/engine - Git at Google

 // Copyright 2013 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "mojo/edk/system/channel.h"

 #include <algorithm>

 #include "base/bind.h"
 #include "base/logging.h"
 #include "base/strings/stringprintf.h"
 #include "mojo/edk/embedder/platform_handle_vector.h"
 #include "mojo/edk/system/endpoint_relayer.h"
 #include "mojo/edk/system/transport_data.h"

 namespace mojo {
 namespace system {

 namespace {

 struct SerializedEndpoint {
   // This is the endpoint ID on the receiving side, and should be a "remote ID".
   // (The receiving side should already have had an endpoint attached and been
   // run via the |Channel|s. This endpoint will have both IDs assigned, so this
   // ID is only needed to associate that endpoint with a particular dispatcher.)
   ChannelEndpointId receiver_endpoint_id;
 };

 }  // namespace

 Channel::Channel(embedder::PlatformSupport* platform_support)
     : platform_support_(platform_support),
       is_running_(false),
       is_shutting_down_(false),
       channel_manager_(nullptr) {
 }

 void Channel::Init(scoped_ptr<RawChannel> raw_channel) {
   DCHECK(creation_thread_checker_.CalledOnValidThread());
   DCHECK(raw_channel);

   // No need to take |mutex_|, since this must be called before this object
   // becomes thread-safe.
   DCHECK(!is_running_);
   raw_channel_ = raw_channel.Pass();
   raw_channel_->Init(this);
   is_running_ = true;
 }

 void Channel::SetChannelManager(ChannelManager* channel_manager) {
   DCHECK(channel_manager);

   MutexLocker locker(&mutex_);
   DCHECK(!is_shutting_down_);
   DCHECK(!channel_manager_);
   channel_manager_ = channel_manager;
 }

 void Channel::Shutdown() {
   DCHECK(creation_thread_checker_.CalledOnValidThread());

   IdToEndpointMap to_destroy;
   {
     MutexLocker locker(&mutex_);
     if (!is_running_)
       return;

     // Note: Don't reset |raw_channel_|, in case we're being called from within
     // |OnReadMessage()| or |OnError()|.
     raw_channel_->Shutdown();
     is_running_ = false;

     // We need to deal with it outside the lock.
     std::swap(to_destroy, local_id_to_endpoint_map_);
   }

   size_t num_live = 0;
   size_t num_zombies = 0;
   for (IdToEndpointMap::iterator it = to_destroy.begin();
        it != to_destroy.end(); ++it) {
     if (it->second) {
       num_live++;
       it->second->DetachFromChannel();
     } else {
       num_zombies++;
     }
   }
   DVLOG_IF(2, num_live || num_zombies) << "Shut down Channel with " << num_live
                                        << " live endpoints and " << num_zombies
                                        << " zombies";
 }

 void Channel::WillShutdownSoon() {
   MutexLocker locker(&mutex_);
   is_shutting_down_ = true;
   channel_manager_ = nullptr;
 }

 void Channel::SetBootstrapEndpoint(scoped_refptr<ChannelEndpoint> endpoint) {
   // Used for both local and remote IDs.
   ChannelEndpointId bootstrap_id = ChannelEndpointId::GetBootstrap();
   SetBootstrapEndpointWithIds(endpoint.Pass(), bootstrap_id, bootstrap_id);
 }

 void Channel::SetBootstrapEndpointWithIds(
     scoped_refptr<ChannelEndpoint> endpoint,
     ChannelEndpointId local_id,
     ChannelEndpointId remote_id) {
   DCHECK(endpoint);

   {
     MutexLocker locker(&mutex_);

     DLOG_IF(WARNING, is_shutting_down_)
         << "SetBootstrapEndpoint() while shutting down";

     // There must not be an endpoint with that ID already.
     DCHECK(local_id_to_endpoint_map_.find(local_id) ==
            local_id_to_endpoint_map_.end());

     local_id_to_endpoint_map_[local_id] = endpoint;
   }

   endpoint->AttachAndRun(this, local_id, remote_id);
 }

 bool Channel::WriteMessage(scoped_ptr<MessageInTransit> message) {
   MutexLocker locker(&mutex_);
   if (!is_running_) {
     // TODO(vtl): I think this is probably not an error condition, but I should
     // think about it (and the shutdown sequence) more carefully.
     LOG(WARNING) << "WriteMessage() after shutdown";
     return false;
   }

   DLOG_IF(WARNING, is_shutting_down_) << "WriteMessage() while shutting down";
   return raw_channel_->WriteMessage(message.Pass());
 }

 bool Channel::IsWriteBufferEmpty() {
   MutexLocker locker(&mutex_);
   if (!is_running_)
     return true;
   return raw_channel_->IsWriteBufferEmpty();
 }

 void Channel::DetachEndpoint(ChannelEndpoint* endpoint,
                              ChannelEndpointId local_id,
                              ChannelEndpointId remote_id) {
   DCHECK(endpoint);
   DCHECK(local_id.is_valid());

   if (!remote_id.is_valid())
     return;  // Nothing to do.

   {
     MutexLocker locker_(&mutex_);
     if (!is_running_)
       return;

     IdToEndpointMap::iterator it = local_id_to_endpoint_map_.find(local_id);
     // We detach immediately if we receive a remove message, so it's possible
     // that the local ID is no longer in |local_id_to_endpoint_map_|, or even
     // that it's since been reused for another endpoint. In both cases, there's
     // nothing more to do.
     if (it == local_id_to_endpoint_map_.end() || it->second.get() != endpoint)
       return;

     DCHECK(it->second);
     it->second = nullptr;

     // Send a remove message outside the lock.
   }

   if (!SendControlMessage(MessageInTransit::Subtype::CHANNEL_REMOVE_ENDPOINT,
                           local_id, remote_id)) {
     HandleLocalError(base::StringPrintf(
                          "Failed to send message to remove remote endpoint "
                          "(local ID %u, remote ID %u)",
                          static_cast<unsigned>(local_id.value()),
                          static_cast<unsigned>(remote_id.value())).c_str());
   }
 }

 size_t Channel::GetSerializedEndpointSize() const {
   return sizeof(SerializedEndpoint);
 }

 void Channel::SerializeEndpointWithClosedPeer(
     void* destination,
     MessageInTransitQueue* message_queue) {
   // We can actually just pass no client to |SerializeEndpointWithLocalPeer()|.
   SerializeEndpointWithLocalPeer(destination, message_queue, nullptr, 0);
 }

 scoped_refptr<ChannelEndpoint> Channel::SerializeEndpointWithLocalPeer(
     void* destination,
     MessageInTransitQueue* message_queue,
     ChannelEndpointClient* endpoint_client,
     unsigned endpoint_client_port) {
   DCHECK(destination);
   // Allow |endpoint_client| to be null, for use by
   // |SerializeEndpointWithClosedPeer()|.

   scoped_refptr<ChannelEndpoint> endpoint(new ChannelEndpoint(
       endpoint_client, endpoint_client_port, message_queue));

   SerializedEndpoint* s = static_cast<SerializedEndpoint*>(destination);
   s->receiver_endpoint_id = AttachAndRunEndpoint(endpoint);
   DVLOG(2) << "Serializing endpoint with local or closed peer (remote ID = "
            << s->receiver_endpoint_id << ")";

   return endpoint;
 }

 void Channel::SerializeEndpointWithRemotePeer(
     void* destination,
     MessageInTransitQueue* message_queue,
     scoped_refptr<ChannelEndpoint> peer_endpoint) {
   DCHECK(destination);
   DCHECK(peer_endpoint);

   DLOG(WARNING) << "Direct message pipe passing across multiple channels not "
                    "yet implemented; will proxy";
   // Create and set up an |EndpointRelayer| to proxy.
   // TODO(vtl): If we were to own/track the relayer directly (rather than owning
   // it via its |ChannelEndpoint|s), then we might be able to make
   // |ChannelEndpoint|'s |client_| pointer a raw pointer.
   scoped_refptr<EndpointRelayer> relayer(new EndpointRelayer());
   scoped_refptr<ChannelEndpoint> endpoint(
       new ChannelEndpoint(relayer.get(), 0, message_queue));
   relayer->Init(endpoint.get(), peer_endpoint.get());
   peer_endpoint->ReplaceClient(relayer.get(), 1);

   SerializedEndpoint* s = static_cast<SerializedEndpoint*>(destination);
   s->receiver_endpoint_id = AttachAndRunEndpoint(endpoint);
   DVLOG(2) << "Serializing endpoint with remote peer (remote ID = "
            << s->receiver_endpoint_id << ")";
 }

 scoped_refptr<IncomingEndpoint> Channel::DeserializeEndpoint(
     const void* source) {
   const SerializedEndpoint* s = static_cast<const SerializedEndpoint*>(source);
   ChannelEndpointId local_id = s->receiver_endpoint_id;
   // No need to check the validity of |local_id| -- if it's not valid, it simply
   // won't be in |incoming_endpoints_|.
   DVLOG_IF(2, !local_id.is_valid() || !local_id.is_remote())
       << "Attempt to get incoming endpoint for invalid ID " << local_id;

   MutexLocker locker(&mutex_);

   auto it = incoming_endpoints_.find(local_id);
   if (it == incoming_endpoints_.end()) {
     LOG(ERROR) << "Failed to deserialize endpoint (ID = " << local_id << ")";
     return nullptr;
   }

   DVLOG(2) << "Deserializing endpoint (new local ID = " << local_id << ")";

   scoped_refptr<IncomingEndpoint> rv;
   rv.swap(it->second);
   incoming_endpoints_.erase(it);
   return rv;
 }

 size_t Channel::GetSerializedPlatformHandleSize() const {
   // TODO(vtl): Having to lock |mutex_| here is a bit unfortunate. Maybe we
   // should get the size in |Init()| and cache it?
   MutexLocker locker(&mutex_);
   return raw_channel_->GetSerializedPlatformHandleSize();
 }

 Channel::~Channel() {
   // The channel should have been shut down first.
   DCHECK(!is_running_);
 }

 void Channel::OnReadMessage(
     const MessageInTransit::View& message_view,
     embedder::ScopedPlatformHandleVectorPtr platform_handles) {
   DCHECK(creation_thread_checker_.CalledOnValidThread());

   switch (message_view.type()) {
     case MessageInTransit::Type::ENDPOINT_CLIENT:
     case MessageInTransit::Type::ENDPOINT:
       OnReadMessageForEndpoint(message_view, platform_handles.Pass());
       break;
     case MessageInTransit::Type::CHANNEL:
       OnReadMessageForChannel(message_view, platform_handles.Pass());
       break;
     default:
       HandleRemoteError(
           base::StringPrintf("Received message of invalid type %u",
                              static_cast<unsigned>(message_view.type()))
               .c_str());
       break;
   }
 }

 void Channel::OnError(Error error) {
   DCHECK(creation_thread_checker_.CalledOnValidThread());

   switch (error) {
     case ERROR_READ_SHUTDOWN:
       // The other side was cleanly closed, so this isn't actually an error.
       DVLOG(1) << "RawChannel read error (shutdown)";
       break;
     case ERROR_READ_BROKEN: {
       MutexLocker locker(&mutex_);
       LOG_IF(ERROR, !is_shutting_down_)
           << "RawChannel read error (connection broken)";
       break;
     }
     case ERROR_READ_BAD_MESSAGE:
       // Receiving a bad message means either a bug, data corruption, or
       // malicious attack (probably due to some other bug).
       LOG(ERROR) << "RawChannel read error (received bad message)";
       break;
     case ERROR_READ_UNKNOWN:
       LOG(ERROR) << "RawChannel read error (unknown)";
       break;
     case ERROR_WRITE:
       // Write errors are slightly notable: they probably shouldn't happen under
       // normal operation (but maybe the other side crashed).
       LOG(WARNING) << "RawChannel write error";
       break;
   }
   Shutdown();
 }

 void Channel::OnReadMessageForEndpoint(
     const MessageInTransit::View& message_view,
     embedder::ScopedPlatformHandleVectorPtr platform_handles) {
   DCHECK(creation_thread_checker_.CalledOnValidThread());
   DCHECK(message_view.type() == MessageInTransit::Type::ENDPOINT_CLIENT ||
          message_view.type() == MessageInTransit::Type::ENDPOINT);

   ChannelEndpointId local_id = message_view.destination_id();
   if (!local_id.is_valid()) {
     HandleRemoteError("Received message with no destination ID");
     return;
   }

   scoped_refptr<ChannelEndpoint> endpoint;
   {
     MutexLocker locker(&mutex_);

     // Since we own |raw_channel_|, and this method and |Shutdown()| should only
     // be called from the creation thread, |raw_channel_| should never be null
     // here.
     DCHECK(is_running_);

     IdToEndpointMap::const_iterator it =
         local_id_to_endpoint_map_.find(local_id);
     if (it != local_id_to_endpoint_map_.end()) {
       // Ignore messages for zombie endpoints (not an error).
       if (!it->second) {
         DVLOG(2) << "Ignoring downstream message for zombie endpoint (local ID "
                     "= " << local_id
                  << ", remote ID = " << message_view.source_id() << ")";
         return;
       }

       endpoint = it->second;
     }
   }
   if (!endpoint) {
     HandleRemoteError(
         base::StringPrintf(
             "Received a message for nonexistent local destination ID %u",
             static_cast<unsigned>(local_id.value())).c_str());
     // This is strongly indicative of some problem. However, it's not a fatal
     // error, since it may indicate a buggy (or hostile) remote process. Don't
     // die even for Debug builds, since handling this properly needs to be
     // tested (TODO(vtl)).
     DLOG(ERROR) << "This should not happen under normal operation.";
     return;
   }

   scoped_ptr<MessageInTransit> message(new MessageInTransit(message_view));
   if (message_view.transport_data_buffer_size() > 0) {
     DCHECK(message_view.transport_data_buffer());
     message->SetDispatchers(TransportData::DeserializeDispatchers(
         message_view.transport_data_buffer(),
         message_view.transport_data_buffer_size(), platform_handles.Pass(),
         this));
   }

   endpoint->OnReadMessage(message.Pass());
 }

 void Channel::OnReadMessageForChannel(
     const MessageInTransit::View& message_view,
     embedder::ScopedPlatformHandleVectorPtr platform_handles) {
   DCHECK(creation_thread_checker_.CalledOnValidThread());
   DCHECK_EQ(message_view.type(), MessageInTransit::Type::CHANNEL);

   // Currently, no channel messages take platform handles.
   if (platform_handles) {
     HandleRemoteError(
         "Received invalid channel message (has platform handles)");
     NOTREACHED();
     return;
   }

   switch (message_view.subtype()) {
     case MessageInTransit::Subtype::CHANNEL_ATTACH_AND_RUN_ENDPOINT:
       DVLOG(2) << "Handling channel message to attach and run endpoint (local "
                   "ID " << message_view.destination_id() << ", remote ID "
                << message_view.source_id() << ")";
       if (!OnAttachAndRunEndpoint(message_view.destination_id(),
                                   message_view.source_id())) {
         HandleRemoteError(
             "Received invalid channel message to attach and run endpoint");
       }
       break;
     case MessageInTransit::Subtype::CHANNEL_REMOVE_ENDPOINT:
       DVLOG(2) << "Handling channel message to remove endpoint (local ID "
                << message_view.destination_id() << ", remote ID "
                << message_view.source_id() << ")";
       if (!OnRemoveEndpoint(message_view.destination_id(),
                             message_view.source_id())) {
         HandleRemoteError(
             "Received invalid channel message to remove endpoint");
       }
       break;
     case MessageInTransit::Subtype::CHANNEL_REMOVE_ENDPOINT_ACK:
       DVLOG(2) << "Handling channel message to ack remove endpoint (local ID "
                << message_view.destination_id() << ", remote ID "
                << message_view.source_id() << ")";
       if (!OnRemoveEndpointAck(message_view.destination_id())) {
         HandleRemoteError(
             "Received invalid channel message to ack remove endpoint");
       }
       break;
     default:
       HandleRemoteError("Received invalid channel message");
       NOTREACHED();
       break;
   }
 }

 bool Channel::OnAttachAndRunEndpoint(ChannelEndpointId local_id,
                                      ChannelEndpointId remote_id) {
   // We should only get this for remotely-created local endpoints, so our local
   // ID should be "remote".
   if (!local_id.is_valid() || !local_id.is_remote()) {
     DVLOG(2) << "Received attach and run endpoint with invalid local ID";
     return false;
   }

   // Conversely, the remote end should be "local".
   if (!remote_id.is_valid() || remote_id.is_remote()) {
     DVLOG(2) << "Received attach and run endpoint with invalid remote ID";
     return false;
   }

   // Create/initialize an |IncomingEndpoint| and thus an endpoint (outside the
   // lock).
   scoped_refptr<IncomingEndpoint> incoming_endpoint(new IncomingEndpoint());
   scoped_refptr<ChannelEndpoint> endpoint = incoming_endpoint->Init();

   bool success = true;
   {
     MutexLocker locker(&mutex_);

     if (local_id_to_endpoint_map_.find(local_id) ==
         local_id_to_endpoint_map_.end()) {
       DCHECK(incoming_endpoints_.find(local_id) == incoming_endpoints_.end());

       // TODO(vtl): Use emplace when we move to C++11 unordered_maps. (It'll
       // avoid some refcount churn.)
       local_id_to_endpoint_map_[local_id] = endpoint;
       incoming_endpoints_[local_id] = incoming_endpoint;
     } else {
       // We need to call |Close()| outside the lock.
       success = false;
     }
   }
   if (!success) {
     DVLOG(2) << "Received attach and run endpoint for existing local ID";
     incoming_endpoint->Close();
     return false;
   }

   endpoint->AttachAndRun(this, local_id, remote_id);
   return true;
 }

 bool Channel::OnRemoveEndpoint(ChannelEndpointId local_id,
                                ChannelEndpointId remote_id) {
   DCHECK(creation_thread_checker_.CalledOnValidThread());

   scoped_refptr<ChannelEndpoint> endpoint;
   {
     MutexLocker locker(&mutex_);

     IdToEndpointMap::iterator it = local_id_to_endpoint_map_.find(local_id);
     if (it == local_id_to_endpoint_map_.end()) {
       DVLOG(2) << "Remove endpoint error: not found";
       return false;
     }

     if (!it->second) {
       // Remove messages "crossed"; we have to wait for the ack.
       return true;
     }

     endpoint = it->second;
     local_id_to_endpoint_map_.erase(it);
     // Detach and send the remove ack message outside the lock.
   }

   endpoint->DetachFromChannel();

   if (!SendControlMessage(
           MessageInTransit::Subtype::CHANNEL_REMOVE_ENDPOINT_ACK, local_id,
           remote_id)) {
     HandleLocalError(base::StringPrintf(
                          "Failed to send message to ack remove remote endpoint "
                          "(local ID %u, remote ID %u)",
                          static_cast<unsigned>(local_id.value()),
                          static_cast<unsigned>(remote_id.value())).c_str());
   }

   return true;
 }

 bool Channel::OnRemoveEndpointAck(ChannelEndpointId local_id) {
   DCHECK(creation_thread_checker_.CalledOnValidThread());

   MutexLocker locker(&mutex_);

   IdToEndpointMap::iterator it = local_id_to_endpoint_map_.find(local_id);
   if (it == local_id_to_endpoint_map_.end()) {
     DVLOG(2) << "Remove endpoint ack error: not found";
     return false;
   }

   if (it->second) {
     DVLOG(2) << "Remove endpoint ack error: wrong state";
     return false;
   }

   local_id_to_endpoint_map_.erase(it);
   return true;
 }

 void Channel::HandleRemoteError(const char* error_message) {
   // TODO(vtl): Is this how we really want to handle this? Probably we want to
   // terminate the connection, since it's spewing invalid stuff.
   LOG(WARNING) << error_message;
 }

 void Channel::HandleLocalError(const char* error_message) {
   // TODO(vtl): Is this how we really want to handle this?
   // Sometimes we'll want to propagate the error back to the message pipe
   // (endpoint), and notify it that the remote is (effectively) closed.
   // Sometimes we'll want to kill the channel (and notify all the endpoints that
   // their remotes are dead.
   LOG(WARNING) << error_message;
 }

 // Note: |endpoint| being a |scoped_refptr| makes this function safe, since it
 // keeps the endpoint alive even after the lock is released. Otherwise, there's
 // the temptation to simply pass the result of |new ChannelEndpoint(...)|
 // directly to this function, which wouldn't be sufficient for safety.
 ChannelEndpointId Channel::AttachAndRunEndpoint(
     scoped_refptr<ChannelEndpoint> endpoint) {
   DCHECK(endpoint);

   ChannelEndpointId local_id;
   ChannelEndpointId remote_id;
   {
     MutexLocker locker(&mutex_);

     DLOG_IF(WARNING, is_shutting_down_)
         << "AttachAndRunEndpoint() while shutting down";

     do {
       local_id = local_id_generator_.GetNext();
     } while (local_id_to_endpoint_map_.find(local_id) !=
              local_id_to_endpoint_map_.end());

     // TODO(vtl): We also need to check for collisions of remote IDs here.
     remote_id = remote_id_generator_.GetNext();

     local_id_to_endpoint_map_[local_id] = endpoint;
   }

   if (!SendControlMessage(
           MessageInTransit::Subtype::CHANNEL_ATTACH_AND_RUN_ENDPOINT, local_id,
           remote_id)) {
     HandleLocalError(base::StringPrintf(
                          "Failed to send message to run remote endpoint (local "
                          "ID %u, remote ID %u)",
                          static_cast<unsigned>(local_id.value()),
                          static_cast<unsigned>(remote_id.value())).c_str());
     // TODO(vtl): Should we continue on to |AttachAndRun()|?
   }

   endpoint->AttachAndRun(this, local_id, remote_id);
   return remote_id;
 }

 bool Channel::SendControlMessage(MessageInTransit::Subtype subtype,
                                  ChannelEndpointId local_id,
                                  ChannelEndpointId remote_id) {
   DVLOG(2) << "Sending channel control message: subtype " << subtype
            << ", local ID " << local_id << ", remote ID " << remote_id;
   scoped_ptr<MessageInTransit> message(new MessageInTransit(
       MessageInTransit::Type::CHANNEL, subtype, 0, nullptr));
   message->set_source_id(local_id);
   message->set_destination_id(remote_id);
   return WriteMessage(message.Pass());
 }

 }  // namespace system
 }  // namespace mojo
	// Copyright 2013 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "mojo/edk/system/channel.h"

	#include <algorithm>

	#include "base/bind.h"
	#include "base/logging.h"
	#include "base/strings/stringprintf.h"
	#include "mojo/edk/embedder/platform_handle_vector.h"
	#include "mojo/edk/system/endpoint_relayer.h"
	#include "mojo/edk/system/transport_data.h"

	namespace mojo {
	namespace system {

	namespace {

	struct SerializedEndpoint {
	// This is the endpoint ID on the receiving side, and should be a "remote ID".
	// (The receiving side should already have had an endpoint attached and been
	// run via the \|Channel\|s. This endpoint will have both IDs assigned, so this
	// ID is only needed to associate that endpoint with a particular dispatcher.)
	ChannelEndpointId receiver_endpoint_id;
	};

	} // namespace

	Channel::Channel(embedder::PlatformSupport* platform_support)
	: platform_support_(platform_support),
	is_running_(false),
	is_shutting_down_(false),
	channel_manager_(nullptr) {
	}

	void Channel::Init(scoped_ptr<RawChannel> raw_channel) {
	DCHECK(creation_thread_checker_.CalledOnValidThread());
	DCHECK(raw_channel);

	// No need to take \|mutex_\|, since this must be called before this object
	// becomes thread-safe.
	DCHECK(!is_running_);
	raw_channel_ = raw_channel.Pass();
	raw_channel_->Init(this);
	is_running_ = true;
	}

	void Channel::SetChannelManager(ChannelManager* channel_manager) {
	DCHECK(channel_manager);

	MutexLocker locker(&mutex_);
	DCHECK(!is_shutting_down_);
	DCHECK(!channel_manager_);
	channel_manager_ = channel_manager;
	}

	void Channel::Shutdown() {
	DCHECK(creation_thread_checker_.CalledOnValidThread());

	IdToEndpointMap to_destroy;
	{
	MutexLocker locker(&mutex_);
	if (!is_running_)
	return;

	// Note: Don't reset \|raw_channel_\|, in case we're being called from within
	// \|OnReadMessage()\| or \|OnError()\|.
	raw_channel_->Shutdown();
	is_running_ = false;

	// We need to deal with it outside the lock.
	std::swap(to_destroy, local_id_to_endpoint_map_);
	}

	size_t num_live = 0;
	size_t num_zombies = 0;
	for (IdToEndpointMap::iterator it = to_destroy.begin();
	it != to_destroy.end(); ++it) {
	if (it->second) {
	num_live++;
	it->second->DetachFromChannel();
	} else {
	num_zombies++;
	}
	}
	DVLOG_IF(2, num_live \|\| num_zombies) << "Shut down Channel with " << num_live
	<< " live endpoints and " << num_zombies
	<< " zombies";
	}

	void Channel::WillShutdownSoon() {
	MutexLocker locker(&mutex_);
	is_shutting_down_ = true;
	channel_manager_ = nullptr;
	}

	void Channel::SetBootstrapEndpoint(scoped_refptr<ChannelEndpoint> endpoint) {
	// Used for both local and remote IDs.
	ChannelEndpointId bootstrap_id = ChannelEndpointId::GetBootstrap();
	SetBootstrapEndpointWithIds(endpoint.Pass(), bootstrap_id, bootstrap_id);
	}

	void Channel::SetBootstrapEndpointWithIds(
	scoped_refptr<ChannelEndpoint> endpoint,
	ChannelEndpointId local_id,
	ChannelEndpointId remote_id) {
	DCHECK(endpoint);

	{
	MutexLocker locker(&mutex_);

	DLOG_IF(WARNING, is_shutting_down_)
	<< "SetBootstrapEndpoint() while shutting down";

	// There must not be an endpoint with that ID already.
	DCHECK(local_id_to_endpoint_map_.find(local_id) ==
	local_id_to_endpoint_map_.end());

	local_id_to_endpoint_map_[local_id] = endpoint;
	}

	endpoint->AttachAndRun(this, local_id, remote_id);
	}

	bool Channel::WriteMessage(scoped_ptr<MessageInTransit> message) {
	MutexLocker locker(&mutex_);
	if (!is_running_) {
	// TODO(vtl): I think this is probably not an error condition, but I should
	// think about it (and the shutdown sequence) more carefully.
	LOG(WARNING) << "WriteMessage() after shutdown";
	return false;
	}

	DLOG_IF(WARNING, is_shutting_down_) << "WriteMessage() while shutting down";
	return raw_channel_->WriteMessage(message.Pass());
	}

	bool Channel::IsWriteBufferEmpty() {
	MutexLocker locker(&mutex_);
	if (!is_running_)
	return true;
	return raw_channel_->IsWriteBufferEmpty();
	}

	void Channel::DetachEndpoint(ChannelEndpoint* endpoint,
	ChannelEndpointId local_id,
	ChannelEndpointId remote_id) {
	DCHECK(endpoint);
	DCHECK(local_id.is_valid());

	if (!remote_id.is_valid())
	return; // Nothing to do.

	{
	MutexLocker locker_(&mutex_);
	if (!is_running_)
	return;

	IdToEndpointMap::iterator it = local_id_to_endpoint_map_.find(local_id);
	// We detach immediately if we receive a remove message, so it's possible
	// that the local ID is no longer in \|local_id_to_endpoint_map_\|, or even
	// that it's since been reused for another endpoint. In both cases, there's
	// nothing more to do.
	if (it == local_id_to_endpoint_map_.end() \|\| it->second.get() != endpoint)
	return;

	DCHECK(it->second);
	it->second = nullptr;

	// Send a remove message outside the lock.
	}

	if (!SendControlMessage(MessageInTransit::Subtype::CHANNEL_REMOVE_ENDPOINT,
	local_id, remote_id)) {
	HandleLocalError(base::StringPrintf(
	"Failed to send message to remove remote endpoint "
	"(local ID %u, remote ID %u)",
	static_cast<unsigned>(local_id.value()),
	static_cast<unsigned>(remote_id.value())).c_str());
	}
	}

	size_t Channel::GetSerializedEndpointSize() const {
	return sizeof(SerializedEndpoint);
	}

	void Channel::SerializeEndpointWithClosedPeer(
	void* destination,
	MessageInTransitQueue* message_queue) {
	// We can actually just pass no client to \|SerializeEndpointWithLocalPeer()\|.
	SerializeEndpointWithLocalPeer(destination, message_queue, nullptr, 0);
	}

	scoped_refptr<ChannelEndpoint> Channel::SerializeEndpointWithLocalPeer(
	void* destination,
	MessageInTransitQueue* message_queue,
	ChannelEndpointClient* endpoint_client,
	unsigned endpoint_client_port) {
	DCHECK(destination);
	// Allow \|endpoint_client\| to be null, for use by
	// \|SerializeEndpointWithClosedPeer()\|.

	scoped_refptr<ChannelEndpoint> endpoint(new ChannelEndpoint(
	endpoint_client, endpoint_client_port, message_queue));

	SerializedEndpoint* s = static_cast<SerializedEndpoint*>(destination);
	s->receiver_endpoint_id = AttachAndRunEndpoint(endpoint);
	DVLOG(2) << "Serializing endpoint with local or closed peer (remote ID = "
	<< s->receiver_endpoint_id << ")";

	return endpoint;
	}

	void Channel::SerializeEndpointWithRemotePeer(
	void* destination,
	MessageInTransitQueue* message_queue,
	scoped_refptr<ChannelEndpoint> peer_endpoint) {
	DCHECK(destination);
	DCHECK(peer_endpoint);

	DLOG(WARNING) << "Direct message pipe passing across multiple channels not "
	"yet implemented; will proxy";
	// Create and set up an \|EndpointRelayer\| to proxy.
	// TODO(vtl): If we were to own/track the relayer directly (rather than owning
	// it via its \|ChannelEndpoint\|s), then we might be able to make
	// \|ChannelEndpoint\|'s \|client_\| pointer a raw pointer.
	scoped_refptr<EndpointRelayer> relayer(new EndpointRelayer());
	scoped_refptr<ChannelEndpoint> endpoint(
	new ChannelEndpoint(relayer.get(), 0, message_queue));
	relayer->Init(endpoint.get(), peer_endpoint.get());
	peer_endpoint->ReplaceClient(relayer.get(), 1);

	SerializedEndpoint* s = static_cast<SerializedEndpoint*>(destination);
	s->receiver_endpoint_id = AttachAndRunEndpoint(endpoint);
	DVLOG(2) << "Serializing endpoint with remote peer (remote ID = "
	<< s->receiver_endpoint_id << ")";
	}

	scoped_refptr<IncomingEndpoint> Channel::DeserializeEndpoint(
	const void* source) {
	const SerializedEndpoint* s = static_cast<const SerializedEndpoint*>(source);
	ChannelEndpointId local_id = s->receiver_endpoint_id;
	// No need to check the validity of \|local_id\| -- if it's not valid, it simply
	// won't be in \|incoming_endpoints_\|.
	DVLOG_IF(2, !local_id.is_valid() \|\| !local_id.is_remote())
	<< "Attempt to get incoming endpoint for invalid ID " << local_id;

	MutexLocker locker(&mutex_);

	auto it = incoming_endpoints_.find(local_id);
	if (it == incoming_endpoints_.end()) {
	LOG(ERROR) << "Failed to deserialize endpoint (ID = " << local_id << ")";
	return nullptr;
	}

	DVLOG(2) << "Deserializing endpoint (new local ID = " << local_id << ")";

	scoped_refptr<IncomingEndpoint> rv;
	rv.swap(it->second);
	incoming_endpoints_.erase(it);
	return rv;
	}

	size_t Channel::GetSerializedPlatformHandleSize() const {
	// TODO(vtl): Having to lock \|mutex_\| here is a bit unfortunate. Maybe we
	// should get the size in \|Init()\| and cache it?
	MutexLocker locker(&mutex_);
	return raw_channel_->GetSerializedPlatformHandleSize();
	}

	Channel::~Channel() {
	// The channel should have been shut down first.
	DCHECK(!is_running_);
	}

	void Channel::OnReadMessage(
	const MessageInTransit::View& message_view,
	embedder::ScopedPlatformHandleVectorPtr platform_handles) {
	DCHECK(creation_thread_checker_.CalledOnValidThread());

	switch (message_view.type()) {
	case MessageInTransit::Type::ENDPOINT_CLIENT:
	case MessageInTransit::Type::ENDPOINT:
	OnReadMessageForEndpoint(message_view, platform_handles.Pass());
	break;
	case MessageInTransit::Type::CHANNEL:
	OnReadMessageForChannel(message_view, platform_handles.Pass());
	break;
	default:
	HandleRemoteError(
	base::StringPrintf("Received message of invalid type %u",
	static_cast<unsigned>(message_view.type()))
	.c_str());
	break;
	}
	}

	void Channel::OnError(Error error) {
	DCHECK(creation_thread_checker_.CalledOnValidThread());

	switch (error) {
	case ERROR_READ_SHUTDOWN:
	// The other side was cleanly closed, so this isn't actually an error.
	DVLOG(1) << "RawChannel read error (shutdown)";
	break;
	case ERROR_READ_BROKEN: {
	MutexLocker locker(&mutex_);
	LOG_IF(ERROR, !is_shutting_down_)
	<< "RawChannel read error (connection broken)";
	break;
	}
	case ERROR_READ_BAD_MESSAGE:
	// Receiving a bad message means either a bug, data corruption, or
	// malicious attack (probably due to some other bug).
	LOG(ERROR) << "RawChannel read error (received bad message)";
	break;
	case ERROR_READ_UNKNOWN:
	LOG(ERROR) << "RawChannel read error (unknown)";
	break;
	case ERROR_WRITE:
	// Write errors are slightly notable: they probably shouldn't happen under
	// normal operation (but maybe the other side crashed).
	LOG(WARNING) << "RawChannel write error";
	break;
	}
	Shutdown();
	}

	void Channel::OnReadMessageForEndpoint(
	const MessageInTransit::View& message_view,
	embedder::ScopedPlatformHandleVectorPtr platform_handles) {
	DCHECK(creation_thread_checker_.CalledOnValidThread());
	DCHECK(message_view.type() == MessageInTransit::Type::ENDPOINT_CLIENT \|\|
	message_view.type() == MessageInTransit::Type::ENDPOINT);

	ChannelEndpointId local_id = message_view.destination_id();
	if (!local_id.is_valid()) {
	HandleRemoteError("Received message with no destination ID");
	return;
	}

	scoped_refptr<ChannelEndpoint> endpoint;
	{
	MutexLocker locker(&mutex_);

	// Since we own \|raw_channel_\|, and this method and \|Shutdown()\| should only
	// be called from the creation thread, \|raw_channel_\| should never be null
	// here.
	DCHECK(is_running_);

	IdToEndpointMap::const_iterator it =
	local_id_to_endpoint_map_.find(local_id);
	if (it != local_id_to_endpoint_map_.end()) {
	// Ignore messages for zombie endpoints (not an error).
	if (!it->second) {
	DVLOG(2) << "Ignoring downstream message for zombie endpoint (local ID "
	"= " << local_id
	<< ", remote ID = " << message_view.source_id() << ")";
	return;
	}

	endpoint = it->second;
	}
	}
	if (!endpoint) {
	HandleRemoteError(
	base::StringPrintf(
	"Received a message for nonexistent local destination ID %u",
	static_cast<unsigned>(local_id.value())).c_str());
	// This is strongly indicative of some problem. However, it's not a fatal
	// error, since it may indicate a buggy (or hostile) remote process. Don't
	// die even for Debug builds, since handling this properly needs to be
	// tested (TODO(vtl)).
	DLOG(ERROR) << "This should not happen under normal operation.";
	return;
	}

	scoped_ptr<MessageInTransit> message(new MessageInTransit(message_view));
	if (message_view.transport_data_buffer_size() > 0) {
	DCHECK(message_view.transport_data_buffer());
	message->SetDispatchers(TransportData::DeserializeDispatchers(
	message_view.transport_data_buffer(),
	message_view.transport_data_buffer_size(), platform_handles.Pass(),
	this));
	}

	endpoint->OnReadMessage(message.Pass());
	}

	void Channel::OnReadMessageForChannel(
	const MessageInTransit::View& message_view,
	embedder::ScopedPlatformHandleVectorPtr platform_handles) {
	DCHECK(creation_thread_checker_.CalledOnValidThread());
	DCHECK_EQ(message_view.type(), MessageInTransit::Type::CHANNEL);

	// Currently, no channel messages take platform handles.
	if (platform_handles) {
	HandleRemoteError(
	"Received invalid channel message (has platform handles)");
	NOTREACHED();
	return;
	}

	switch (message_view.subtype()) {
	case MessageInTransit::Subtype::CHANNEL_ATTACH_AND_RUN_ENDPOINT:
	DVLOG(2) << "Handling channel message to attach and run endpoint (local "
	"ID " << message_view.destination_id() << ", remote ID "
	<< message_view.source_id() << ")";
	if (!OnAttachAndRunEndpoint(message_view.destination_id(),
	message_view.source_id())) {
	HandleRemoteError(
	"Received invalid channel message to attach and run endpoint");
	}
	break;
	case MessageInTransit::Subtype::CHANNEL_REMOVE_ENDPOINT:
	DVLOG(2) << "Handling channel message to remove endpoint (local ID "
	<< message_view.destination_id() << ", remote ID "
	<< message_view.source_id() << ")";
	if (!OnRemoveEndpoint(message_view.destination_id(),
	message_view.source_id())) {
	HandleRemoteError(
	"Received invalid channel message to remove endpoint");
	}
	break;
	case MessageInTransit::Subtype::CHANNEL_REMOVE_ENDPOINT_ACK:
	DVLOG(2) << "Handling channel message to ack remove endpoint (local ID "
	<< message_view.destination_id() << ", remote ID "
	<< message_view.source_id() << ")";
	if (!OnRemoveEndpointAck(message_view.destination_id())) {
	HandleRemoteError(
	"Received invalid channel message to ack remove endpoint");
	}
	break;
	default:
	HandleRemoteError("Received invalid channel message");
	NOTREACHED();
	break;
	}
	}

	bool Channel::OnAttachAndRunEndpoint(ChannelEndpointId local_id,
	ChannelEndpointId remote_id) {
	// We should only get this for remotely-created local endpoints, so our local
	// ID should be "remote".
	if (!local_id.is_valid() \|\| !local_id.is_remote()) {
	DVLOG(2) << "Received attach and run endpoint with invalid local ID";
	return false;
	}

	// Conversely, the remote end should be "local".
	if (!remote_id.is_valid() \|\| remote_id.is_remote()) {
	DVLOG(2) << "Received attach and run endpoint with invalid remote ID";
	return false;
	}

	// Create/initialize an \|IncomingEndpoint\| and thus an endpoint (outside the
	// lock).
	scoped_refptr<IncomingEndpoint> incoming_endpoint(new IncomingEndpoint());
	scoped_refptr<ChannelEndpoint> endpoint = incoming_endpoint->Init();

	bool success = true;
	{
	MutexLocker locker(&mutex_);

	if (local_id_to_endpoint_map_.find(local_id) ==
	local_id_to_endpoint_map_.end()) {
	DCHECK(incoming_endpoints_.find(local_id) == incoming_endpoints_.end());

	// TODO(vtl): Use emplace when we move to C++11 unordered_maps. (It'll
	// avoid some refcount churn.)
	local_id_to_endpoint_map_[local_id] = endpoint;
	incoming_endpoints_[local_id] = incoming_endpoint;
	} else {
	// We need to call \|Close()\| outside the lock.
	success = false;
	}
	}
	if (!success) {
	DVLOG(2) << "Received attach and run endpoint for existing local ID";
	incoming_endpoint->Close();
	return false;
	}

	endpoint->AttachAndRun(this, local_id, remote_id);
	return true;
	}

	bool Channel::OnRemoveEndpoint(ChannelEndpointId local_id,
	ChannelEndpointId remote_id) {
	DCHECK(creation_thread_checker_.CalledOnValidThread());

	scoped_refptr<ChannelEndpoint> endpoint;
	{
	MutexLocker locker(&mutex_);

	IdToEndpointMap::iterator it = local_id_to_endpoint_map_.find(local_id);
	if (it == local_id_to_endpoint_map_.end()) {
	DVLOG(2) << "Remove endpoint error: not found";
	return false;
	}

	if (!it->second) {
	// Remove messages "crossed"; we have to wait for the ack.
	return true;
	}

	endpoint = it->second;
	local_id_to_endpoint_map_.erase(it);
	// Detach and send the remove ack message outside the lock.
	}

	endpoint->DetachFromChannel();

	if (!SendControlMessage(
	MessageInTransit::Subtype::CHANNEL_REMOVE_ENDPOINT_ACK, local_id,
	remote_id)) {
	HandleLocalError(base::StringPrintf(
	"Failed to send message to ack remove remote endpoint "
	"(local ID %u, remote ID %u)",
	static_cast<unsigned>(local_id.value()),
	static_cast<unsigned>(remote_id.value())).c_str());
	}

	return true;
	}

	bool Channel::OnRemoveEndpointAck(ChannelEndpointId local_id) {
	DCHECK(creation_thread_checker_.CalledOnValidThread());

	MutexLocker locker(&mutex_);

	IdToEndpointMap::iterator it = local_id_to_endpoint_map_.find(local_id);
	if (it == local_id_to_endpoint_map_.end()) {
	DVLOG(2) << "Remove endpoint ack error: not found";
	return false;
	}

	if (it->second) {
	DVLOG(2) << "Remove endpoint ack error: wrong state";
	return false;
	}

	local_id_to_endpoint_map_.erase(it);
	return true;
	}

	void Channel::HandleRemoteError(const char* error_message) {
	// TODO(vtl): Is this how we really want to handle this? Probably we want to
	// terminate the connection, since it's spewing invalid stuff.
	LOG(WARNING) << error_message;
	}

	void Channel::HandleLocalError(const char* error_message) {
	// TODO(vtl): Is this how we really want to handle this?
	// Sometimes we'll want to propagate the error back to the message pipe
	// (endpoint), and notify it that the remote is (effectively) closed.
	// Sometimes we'll want to kill the channel (and notify all the endpoints that
	// their remotes are dead.
	LOG(WARNING) << error_message;
	}

	// Note: \|endpoint\| being a \|scoped_refptr\| makes this function safe, since it
	// keeps the endpoint alive even after the lock is released. Otherwise, there's
	// the temptation to simply pass the result of \|new ChannelEndpoint(...)\|
	// directly to this function, which wouldn't be sufficient for safety.
	ChannelEndpointId Channel::AttachAndRunEndpoint(
	scoped_refptr<ChannelEndpoint> endpoint) {
	DCHECK(endpoint);

	ChannelEndpointId local_id;
	ChannelEndpointId remote_id;
	{
	MutexLocker locker(&mutex_);

	DLOG_IF(WARNING, is_shutting_down_)
	<< "AttachAndRunEndpoint() while shutting down";

	do {
	local_id = local_id_generator_.GetNext();
	} while (local_id_to_endpoint_map_.find(local_id) !=
	local_id_to_endpoint_map_.end());

	// TODO(vtl): We also need to check for collisions of remote IDs here.
	remote_id = remote_id_generator_.GetNext();

	local_id_to_endpoint_map_[local_id] = endpoint;
	}

	if (!SendControlMessage(
	MessageInTransit::Subtype::CHANNEL_ATTACH_AND_RUN_ENDPOINT, local_id,
	remote_id)) {
	HandleLocalError(base::StringPrintf(
	"Failed to send message to run remote endpoint (local "
	"ID %u, remote ID %u)",
	static_cast<unsigned>(local_id.value()),
	static_cast<unsigned>(remote_id.value())).c_str());
	// TODO(vtl): Should we continue on to \|AttachAndRun()\|?
	}

	endpoint->AttachAndRun(this, local_id, remote_id);
	return remote_id;
	}

	bool Channel::SendControlMessage(MessageInTransit::Subtype subtype,
	ChannelEndpointId local_id,
	ChannelEndpointId remote_id) {
	DVLOG(2) << "Sending channel control message: subtype " << subtype
	<< ", local ID " << local_id << ", remote ID " << remote_id;
	scoped_ptr<MessageInTransit> message(new MessageInTransit(
	MessageInTransit::Type::CHANNEL, subtype, 0, nullptr));
	message->set_source_id(local_id);
	message->set_destination_id(remote_id);
	return WriteMessage(message.Pass());
	}

	} // namespace system
	} // namespace mojo